A system and a process configuration generates a unitary rendered image for a video from at least two cameras. The configuration detects a communication coupling of at least two cameras and determines a master camera and a slave camera. The configuration determines an orientation of camera sensor of the master camera and the slave camera and determines a first frame of a video for a synchronization point for a start of a video capture. The configuration captures and reads images from the master camera sensor and the slave camera sensor in response to the start of the video capture and orientation of the camera sensors.

The present invention provides a portable device includes a control unit; a first and a second image capturing device coupled to the control unit; a wide angle image generating module coupled to the control unit to activate the first and the second image capturing device, simultaneously for taking a first picture by the first image capturing device and a second picture by the second image capturing device respectively; a stitching module coupled to the control unit to combine the first picture and the second picture to form a wide view angle image; and a display coupled to the control unit for displaying the wide view angle image.

An image processor is provided for correcting brightness of saturated pixels of a captured image. The image processor can include a pixel saturation determiner that whether one or more pixels in an image sensor have been saturated by comparing pixel brightness levels of the pixels to a predetermined saturation threshold. Moreover, the image processor includes an image enhancer that generates a corrected image without artifacts due to the saturated pixel(s) by replacing the pixel brightness of the saturated pixel(s) with a pixel correction value that is based on a pixel brightness of one or more unsaturated pixel in the image sensor.

A solid-state imaging device includes a plurality of pixels each including a photoelectric conversion unit, a charge accumulating portion accumulating signal charges transferred from the photoelectric conversion unit, a floating diffusion portion accumulating signal charges transferred from the charge accumulating portion, and a read-out unit transferring signal charges from the charge accumulating portion to the floating diffusion portion and output a signal corresponding to the signal charges, and a control unit controlling the read-out unit to start, after starting read-out of signals of one frame from the charge accumulating portions, an accumulation of signal charges for a next frame at the photoelectric conversion units simultaneously, and to start, before completing the read-out of the signal of the one frame, an accumulation of signal charges at the charge accumulating portion of a pixel among the plurality of pixels from which the signal of the one frame is already read out.

Provided is an image processing apparatus for correcting blinking defect noise included in image data generated by an image sensor, the image sensor including pixels arranged two-dimensionally and read-out circuits configured to read out a pixel value. The image processing apparatus is configured to: acquire noise information that associates the pixel value with positional information of the read-out circuits or positional information of each of the pixels, and with feature data related to blinking defect noise attributed to the read-out circuits; determine whether the blinking defect noise occurs on a pixel of interest based on the noise information; calculate candidate values indicating a correction amount for correcting the blinking defect noise based on the noise information and a pixel value of the pixel of interest if the blinking defect noise occurs; and correct the pixel value of the pixel of interest based on the candidate values.

A computing device and a method detect a lightness of a lighting device. The computing device captures an image of the lighting device and parses the image to obtain a pixel gray value of each lighting dot of the lighting device. The computing device obtains detection information of the lighting device according to the pixel gray value of each lighting dot of the lighting device. The computing device generates a detection report of the lighting device according to the detection information of the lighting device.

An image sensor system with an image sensor that generates a first image and a second image. The first and second images are transmitted to a processor in a time overlapping manner. By way of example, the images may be transferred to the processor in an interleaving manner or provided on separate dedicated busses.

An optical apparatus captures images of a wide-angle scene with a single camera having a continuous panomorph zoom distortion profile. When combined with a processing unit, the hybrid zoom system creates an output image with constant resolution while allowing continuous adjustment in the magnification and field of view of the image without interpolation like a digital zoom system or without any moving parts like an optical zoom system.

An imaging device includes: first and second image sensors; a first communication controller configured to be connected to the first image sensor; a first clock generator that generates a first clock signal that is a reference for operation of the first communication controller; a second communication controller configured to be connected to the second image sensor; a second clock generator that generates a second clock signal that is a reference for operation of the second communication controller; a reference synchronization signal generator that generates a reference synchronization signal; and an imaging synchronization signal generator that generates an imaging synchronization signal which is a trigger for determining timings of imaging by the first and second image sensors, and outputs the imaging synchronization signal to the first and second communication controllers at a timing when a predetermined period of time has elapsed from a reference timing based on the reference synchronization signal.

A mobile electronic device includes a first camera configured to capture a first image of a subject in a first field of view and including an RGB array, a second camera configured to capture a second image of the subject in a second field of view that is different from the first field of view and including an RGBW array; and an image processor configured to generate a target image using at least one of the first or second images in accordance with a selected mode of a plurality of modes. The plurality of modes includes still image modes and video modes associated with separate, respective combinations of output speed and bit depth such that the image processor is configured to control an output of the second camera to have a different combination of output speed and bit depth based on the selected mode.